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import gc
import random
import eventlet
from eventlet import hubs, pools
from eventlet.support import greenlets as greenlet
import six
import tests
def passthru(a):
eventlet.sleep(0.01)
return a
def passthru2(a, b):
eventlet.sleep(0.01)
return a, b
def raiser(exc):
raise exc
class GreenPool(tests.LimitedTestCase):
def test_spawn(self):
p = eventlet.GreenPool(4)
waiters = []
for i in range(10):
waiters.append(p.spawn(passthru, i))
results = [waiter.wait() for waiter in waiters]
self.assertEqual(results, list(range(10)))
def test_spawn_n(self):
p = eventlet.GreenPool(4)
results_closure = []
def do_something(a):
eventlet.sleep(0.01)
results_closure.append(a)
for i in range(10):
p.spawn(do_something, i)
p.waitall()
self.assertEqual(results_closure, list(range(10)))
def test_waiting(self):
pool = eventlet.GreenPool(1)
done = eventlet.Event()
def consume():
done.wait()
def waiter(pool):
gt = pool.spawn(consume)
gt.wait()
waiters = []
self.assertEqual(pool.running(), 0)
waiters.append(eventlet.spawn(waiter, pool))
eventlet.sleep(0)
self.assertEqual(pool.waiting(), 0)
waiters.append(eventlet.spawn(waiter, pool))
eventlet.sleep(0)
self.assertEqual(pool.waiting(), 1)
waiters.append(eventlet.spawn(waiter, pool))
eventlet.sleep(0)
self.assertEqual(pool.waiting(), 2)
self.assertEqual(pool.running(), 1)
done.send(None)
for w in waiters:
w.wait()
self.assertEqual(pool.waiting(), 0)
self.assertEqual(pool.running(), 0)
def test_multiple_coros(self):
evt = eventlet.Event()
results = []
def producer():
results.append('prod')
evt.send()
def consumer():
results.append('cons1')
evt.wait()
results.append('cons2')
pool = eventlet.GreenPool(2)
done = pool.spawn(consumer)
pool.spawn_n(producer)
done.wait()
self.assertEqual(['cons1', 'prod', 'cons2'], results)
def test_timer_cancel(self):
# this test verifies that local timers are not fired
# outside of the context of the spawn
timer_fired = []
def fire_timer():
timer_fired.append(True)
def some_work():
hubs.get_hub().schedule_call_local(0, fire_timer)
pool = eventlet.GreenPool(2)
worker = pool.spawn(some_work)
worker.wait()
eventlet.sleep(0)
eventlet.sleep(0)
self.assertEqual(timer_fired, [])
def test_reentrant(self):
pool = eventlet.GreenPool(1)
def reenter():
waiter = pool.spawn(lambda a: a, 'reenter')
self.assertEqual('reenter', waiter.wait())
outer_waiter = pool.spawn(reenter)
outer_waiter.wait()
evt = eventlet.Event()
def reenter_async():
pool.spawn_n(lambda a: a, 'reenter')
evt.send('done')
pool.spawn_n(reenter_async)
self.assertEqual('done', evt.wait())
def assert_pool_has_free(self, pool, num_free):
self.assertEqual(pool.free(), num_free)
def wait_long_time(e):
e.wait()
timer = eventlet.Timeout(1)
try:
evt = eventlet.Event()
for x in six.moves.range(num_free):
pool.spawn(wait_long_time, evt)
# if the pool has fewer free than we expect,
# then we'll hit the timeout error
finally:
timer.cancel()
# if the runtime error is not raised it means the pool had
# some unexpected free items
timer = eventlet.Timeout(0, RuntimeError)
try:
self.assertRaises(RuntimeError, pool.spawn, wait_long_time, evt)
finally:
timer.cancel()
# clean up by causing all the wait_long_time functions to return
evt.send(None)
eventlet.sleep(0)
eventlet.sleep(0)
def test_resize(self):
pool = eventlet.GreenPool(2)
evt = eventlet.Event()
def wait_long_time(e):
e.wait()
pool.spawn(wait_long_time, evt)
pool.spawn(wait_long_time, evt)
self.assertEqual(pool.free(), 0)
self.assertEqual(pool.running(), 2)
self.assert_pool_has_free(pool, 0)
# verify that the pool discards excess items put into it
pool.resize(1)
# cause the wait_long_time functions to return, which will
# trigger puts to the pool
evt.send(None)
eventlet.sleep(0)
eventlet.sleep(0)
self.assertEqual(pool.free(), 1)
self.assertEqual(pool.running(), 0)
self.assert_pool_has_free(pool, 1)
# resize larger and assert that there are more free items
pool.resize(2)
self.assertEqual(pool.free(), 2)
self.assertEqual(pool.running(), 0)
self.assert_pool_has_free(pool, 2)
def test_pool_smash(self):
# The premise is that a coroutine in a Pool tries to get a token out
# of a token pool but times out before getting the token. We verify
# that neither pool is adversely affected by this situation.
pool = eventlet.GreenPool(1)
tp = pools.TokenPool(max_size=1)
tp.get() # empty out the pool
def do_receive(tp):
timer = eventlet.Timeout(0, RuntimeError())
try:
tp.get()
self.fail("Shouldn't have received anything from the pool")
except RuntimeError:
return 'timed out'
else:
timer.cancel()
# the spawn makes the token pool expect that coroutine, but then
# immediately cuts bait
e1 = pool.spawn(do_receive, tp)
self.assertEqual(e1.wait(), 'timed out')
# the pool can get some random item back
def send_wakeup(tp):
tp.put('wakeup')
gt = eventlet.spawn(send_wakeup, tp)
# now we ask the pool to run something else, which should not
# be affected by the previous send at all
def resume():
return 'resumed'
e2 = pool.spawn(resume)
self.assertEqual(e2.wait(), 'resumed')
# we should be able to get out the thing we put in there, too
self.assertEqual(tp.get(), 'wakeup')
gt.wait()
def test_spawn_n_2(self):
p = eventlet.GreenPool(2)
self.assertEqual(p.free(), 2)
r = []
def foo(a):
r.append(a)
gt = p.spawn(foo, 1)
self.assertEqual(p.free(), 1)
gt.wait()
self.assertEqual(r, [1])
eventlet.sleep(0)
self.assertEqual(p.free(), 2)
# Once the pool is exhausted, spawning forces a yield.
p.spawn_n(foo, 2)
self.assertEqual(1, p.free())
self.assertEqual(r, [1])
p.spawn_n(foo, 3)
self.assertEqual(0, p.free())
self.assertEqual(r, [1])
p.spawn_n(foo, 4)
self.assertEqual(set(r), set([1, 2, 3]))
eventlet.sleep(0)
self.assertEqual(set(r), set([1, 2, 3, 4]))
def test_exceptions(self):
p = eventlet.GreenPool(2)
for m in (p.spawn, p.spawn_n):
self.assert_pool_has_free(p, 2)
m(raiser, RuntimeError())
self.assert_pool_has_free(p, 1)
p.waitall()
self.assert_pool_has_free(p, 2)
m(raiser, greenlet.GreenletExit)
self.assert_pool_has_free(p, 1)
p.waitall()
self.assert_pool_has_free(p, 2)
def test_imap(self):
p = eventlet.GreenPool(4)
result_list = list(p.imap(passthru, range(10)))
self.assertEqual(result_list, list(range(10)))
def test_empty_imap(self):
p = eventlet.GreenPool(4)
result_iter = p.imap(passthru, [])
self.assertRaises(StopIteration, result_iter.next)
def test_imap_nonefunc(self):
p = eventlet.GreenPool(4)
result_list = list(p.imap(None, range(10)))
self.assertEqual(result_list, [(x,) for x in range(10)])
def test_imap_multi_args(self):
p = eventlet.GreenPool(4)
result_list = list(p.imap(passthru2, range(10), range(10, 20)))
self.assertEqual(result_list, list(zip(range(10), range(10, 20))))
def test_imap_raises(self):
# testing the case where the function raises an exception;
# both that the caller sees that exception, and that the iterator
# continues to be usable to get the rest of the items
p = eventlet.GreenPool(4)
def raiser(item):
if item == 1 or item == 7:
raise RuntimeError("intentional error")
else:
return item
it = p.imap(raiser, range(10))
results = []
while True:
try:
results.append(six.next(it))
except RuntimeError:
results.append('r')
except StopIteration:
break
self.assertEqual(results, [0, 'r', 2, 3, 4, 5, 6, 'r', 8, 9])
def test_starmap(self):
p = eventlet.GreenPool(4)
result_list = list(p.starmap(passthru, [(x,) for x in range(10)]))
self.assertEqual(result_list, list(range(10)))
def test_waitall_on_nothing(self):
p = eventlet.GreenPool()
p.waitall()
def test_recursive_waitall(self):
p = eventlet.GreenPool()
gt = p.spawn(p.waitall)
self.assertRaises(AssertionError, gt.wait)
class GreenPile(tests.LimitedTestCase):
def test_pile(self):
p = eventlet.GreenPile(4)
for i in range(10):
p.spawn(passthru, i)
result_list = list(p)
self.assertEqual(result_list, list(range(10)))
def test_pile_spawn_times_out(self):
p = eventlet.GreenPile(4)
for i in range(4):
p.spawn(passthru, i)
# now it should be full and this should time out
eventlet.Timeout(0)
self.assertRaises(eventlet.Timeout, p.spawn, passthru, "time out")
# verify that the spawn breakage didn't interrupt the sequence
# and terminates properly
for i in range(4, 10):
p.spawn(passthru, i)
self.assertEqual(list(p), list(range(10)))
def test_empty_pile(self):
p = eventlet.GreenPile(4)
# no spawn()s
# If this hangs, LimitedTestCase should time out
self.assertEqual(list(p), [])
def test_constructing_from_pool(self):
pool = eventlet.GreenPool(2)
pile1 = eventlet.GreenPile(pool)
pile2 = eventlet.GreenPile(pool)
def bunch_of_work(pile, unique):
for i in range(10):
pile.spawn(passthru, i + unique)
eventlet.spawn(bunch_of_work, pile1, 0)
eventlet.spawn(bunch_of_work, pile2, 100)
eventlet.sleep(0)
self.assertEqual(list(pile2), list(range(100, 110)))
self.assertEqual(list(pile1), list(range(10)))
def test_greenpool_type_check():
eventlet.GreenPool(0)
eventlet.GreenPool(1)
eventlet.GreenPool(1e3)
with tests.assert_raises(TypeError):
eventlet.GreenPool('foo')
with tests.assert_raises(ValueError):
eventlet.GreenPool(-1)
class StressException(Exception):
pass
r = random.Random(0)
def pressure(arg):
while r.random() < 0.5:
eventlet.sleep(r.random() * 0.001)
if r.random() < 0.8:
return arg
else:
raise StressException(arg)
def passthru(arg):
while r.random() < 0.5:
eventlet.sleep(r.random() * 0.001)
return arg
class Stress(tests.LimitedTestCase):
# tests will take extra-long
TEST_TIMEOUT = 60
def spawn_order_check(self, concurrency):
# checks that piles are strictly ordered
p = eventlet.GreenPile(concurrency)
def makework(count, unique):
for i in six.moves.range(count):
token = (unique, i)
p.spawn(pressure, token)
iters = 1000
eventlet.spawn(makework, iters, 1)
eventlet.spawn(makework, iters, 2)
eventlet.spawn(makework, iters, 3)
p.spawn(pressure, (0, 0))
latest = [-1] * 4
received = 0
it = iter(p)
while True:
try:
i = six.next(it)
except StressException as exc:
i = exc.args[0]
except StopIteration:
break
received += 1
if received % 5 == 0:
eventlet.sleep(0.0001)
unique, order = i
assert latest[unique] < order
latest[unique] = order
for l in latest[1:]:
self.assertEqual(l, iters - 1)
def test_ordering_5(self):
self.spawn_order_check(5)
def test_ordering_50(self):
self.spawn_order_check(50)
def imap_memory_check(self, concurrency):
# checks that imap is strictly
# ordered and consumes a constant amount of memory
p = eventlet.GreenPool(concurrency)
count = 1000
it = p.imap(passthru, six.moves.range(count))
latest = -1
while True:
try:
i = six.next(it)
except StopIteration:
break
if latest == -1:
gc.collect()
initial_obj_count = len(gc.get_objects())
assert i > latest
latest = i
if latest % 5 == 0:
eventlet.sleep(0.001)
if latest % 10 == 0:
gc.collect()
objs_created = len(gc.get_objects()) - initial_obj_count
assert objs_created < 25 * concurrency, objs_created
# make sure we got to the end
self.assertEqual(latest, count - 1)
def test_imap_50(self):
self.imap_memory_check(50)
def test_imap_500(self):
self.imap_memory_check(500)
def test_with_intpool(self):
class IntPool(pools.Pool):
def create(self):
self.current_integer = getattr(self, 'current_integer', 0) + 1
return self.current_integer
def subtest(intpool_size, pool_size, num_executes):
def run(int_pool):
token = int_pool.get()
eventlet.sleep(0.0001)
int_pool.put(token)
return token
int_pool = IntPool(max_size=intpool_size)
pool = eventlet.GreenPool(pool_size)
for ix in six.moves.range(num_executes):
pool.spawn(run, int_pool)
pool.waitall()
subtest(4, 7, 7)
subtest(50, 75, 100)
for isize in (10, 20, 30, 40, 50):
for psize in (5, 25, 35, 50):
subtest(isize, psize, psize)
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